Control circuit and method therefor

ABSTRACT

In one embodiment, a control circuit may be configured to form a switching signal to switch a power transistor at a frequency to regulate an output voltage of the power supply to a target value wherein the control circuit is configured to operate in a normal operating mode and a start-up mode and wherein the control circuit is configured to switch the switching signal at a target frequency in response to operating in the normal operating mode. A first circuit may be configured to control the frequency of the switching signal to increase from a first frequency to a second frequency that is less than the target frequency in response to operating in the start-up mode.

PRIORITY CLAIM TO PRIOR PROVISIONAL FILING

This application claims priority to prior filed Provisional ApplicationNo. 62/416,920 entitled “STEPWISE SOFT-START CIRCUIT WITH GRADUALFREQUENCY SETTLEMENT FOR POWER CONVERTERS” filed on Nov. 3, 2016, andhaving common inventors Chiu et al. which is hereby incorporated hereinby reference

BACKGROUND OF THE INVENTION

The present invention relates, in general, to electronics, and moreparticularly, to semiconductors, structures thereof, and methods offorming semiconductor devices.

In the past, the electronics industry utilized various methods andstructures to form power converters for use with various electronicdevices such as home appliances, computers, battery chargers etc. Thepower converters were used to provide regulated power for electronicdevices. However, many conventional power converters had an initialringing and/or spike phenomenon in the inductor current such as forexample when starting up from an initial power on sequence andespecially when the output voltage was low. The initial ringing and/orspiking could adversely affect the regulation of the power converters.

Accordingly, it is desirable to provide a power converter that reducesthe initial ringing and/or spiking or that improves the regulation.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 schematically illustrates an example of a portion of anembodiment of a flyback power supply system in accordance with thepresent invention;

FIG. 2A schematically illustrates an example of a portion of anembodiment of a circuit of the system of FIG. 1 in accordance with thepresent invention;

FIG. 2B is a graph having a plot that illustrates an example of anembodiment of a signal of the circuit of

FIG. 2A in accordance with the present invention;

FIG. 3A schematically illustrates an example of a portion of anembodiment of a circuit that may be an alternate embodiment of one ofthe circuits of FIG. 2A in accordance with the present invention.

FIG. 3B is a graph having plots that illustrate some of the signalsformed during an example of an operation of the circuit of FIG. 3A inaccordance with the present invention;

FIG. 4A schematically illustrates an example of a portion of anoscillator circuit that may have an embodiment that may be an alternateembodiment of one of the circuits of FIG. 2A in accordance with thepresent invention;

FIG. 4B is a graph having plots that illustrate some of the signalsformed during an example of an embodiment of operation of the circuit ofFIG. 4A in accordance with the present invention;

FIG. 5A schematically illustrates an example of a portion of anembodiment of a control circuit that may have an embodiment that may bean alternate embodiment of one of the circuits of FIG. 2A;

FIG. 5B is a graph having plots that illustrate examples of some of thesignals that may be formed during an example of an operation of anembodiment of the circuit of FIG, 5A in accordance with the presentinvention;

FIG. 6A schematically illustrates an example of a portion of anembodiment of a selection circuit that may have an embodiment that maybe an alternate embodiment of one of the circuits of FIG. 5A inaccordance with the present invention;

FIG. 6B schematically illustrates an example of a portion of anembodiment of another selection circuit that may have an embodiment thatmay be an alternate embodiment of one of the circuits of FIG. 5A inaccordance with the present invention;

FIG. 7A schematically illustrates an example of a portion of anembodiment of a control circuit that may have an embodiment that may bean alternate embodiment of one of the circuits of FIG. 2A in accordancewith the present invention;

FIG. 7B is a graph having plots that illustrate examples of some of thesignals that may be formed during an example of an operation of anembodiment of the circuit of FIG. 7A in accordance with the presentinvention;

FIG. 8 schematically illustrates an example of a portion of anembodiment of a buck power supply system in accordance with the presentinvention; and

FIG. 9 illustrates an enlarged plan view of a portion of an embodimentof a semiconductor device that may include one of the circuits of FIGS.2A, 5A, or 7A in accordance with the present invention.

For simplicity and clarity of the illustration(s), elements in thefigures are not necessarily to scale, some of the elements may beexaggerated for illustrative purposes, and the same reference numbers indifferent figures denote the same elements, unless stated otherwise.Additionally, descriptions and details of well-known steps and elementsmay be omitted for simplicity of the description. As used herein currentcarrying element or current carrying electrode means an element of adevice that carries current through the device such as a source or adrain of an MOS transistor or an emitter or a collector of a bipolartransistor or a cathode or anode of a diode, and a control element orcontrol electrode means an element of the device that controls currentthrough the device such as a gate of an MOS transistor or a base of abipolar transistor. Additionally, one current carrying element may carrycurrent in one direction through a device, such as carry currententering the device, and a second current carrying element may carrycurrent in an opposite direction through the device, such as carrycurrent leaving the device. Although the devices may be explained hereinas certain N-channel or P-channel devices, or certain N-type or P-typedoped regions, a person of ordinary skill in the art will appreciatethat complementary devices are also possible in accordance with thepresent invention. One of ordinary skill in the art understands that theconductivity type refers to the mechanism through which conductionoccurs such as through conduction of holes or electrons, therefore, thatconductivity type does not refer to the doping concentration but thedoping type, such as P-type or N-type. It will be appreciated by thoseskilled in the art that the words during, while, and when as used hereinrelating to circuit operation are not exact terms that mean an actiontakes place instantly upon an initiating action but that there may besome small but reasonable delay(s), such as various propagation delays,between the reaction that is initiated by the initial action.Additionally, the term while means that a certain action occurs at leastwithin some portion of a duration of the initiating action. The use ofthe word approximately or substantially means that a value of an elementhas a parameter that is expected to be close to a stated value orposition. However, as is well known in the art there are always minorvariances that prevent the values or positions from being exactly asstated. It is well established in the art that variances of up to atleast ten per cent (10%) (and up to twenty per cent (20%) for someelements including semiconductor doping concentrations) are reasonablevariances from the ideal goal of exactly as described. When used inreference to a state of a signal, the term “asserted” means an activestate of the signal and the term “negated” means an inactive state ofthe signal. The actual voltage value or logic state (such as a “1” or a“0”) of the signal depends on whether positive or negative logic isused. Thus, asserted can be either a high voltage or a high logic or alow voltage or low logic depending on whether positive or negative logicis used and negated may be either a low voltage or low state or a highvoltage or high logic depending on whether positive or negative logic isused. Herein, a positive logic convention is used, but those skilled inthe art understand that a negative logic convention could also be used.The terms first, second, third and the like in the claims or/and in theDetailed Description of the Drawings, as used in a portion of a name ofan element are used for distinguishing between similar elements and notnecessarily for describing a sequence, either temporally, spatially, inranking or in any other manner. It is to be understood that the terms soused are interchangeable under appropriate circumstances and that theembodiments described herein are capable of operation in other sequencesthan described or illustrated herein. Reference to “one embodiment” or“an embodiment” means that a particular feature, structure orcharacteristic described in connection with the embodiment is includedin at least one embodiment of the present invention. Thus, appearancesof the phrases “in one embodiment” or “in an embodiment” in variousplaces throughout this specification are not necessarily all referringto the same embodiment, but in some cases it may. Furthermore, theparticular features, structures, or characteristics may be combined inany suitable manner, as would be apparent to one of ordinary skill inthe art, in one or more embodiments.

The embodiments illustrated and described hereinafter suitably may haveembodiments and/or may be practiced in the absence of any element whichis not specifically disclosed herein.

DETAILED DESCRIPTION

FIG. 1 schematically illustrates an example of a portion of anembodiment of a flyback power supply system 50. System 50 includes atransformer 10 that has a primary winding Np, a secondary winding Ns,and may optionally include an auxiliary winding Na. The primary windingNp is connected to receive an input voltage V_(IN) from an inputterminal of system 50. Input voltage V_(IN) may be a rectified DCvoltage that is formed from rectifying an AC voltage or alternately maybe a DC voltage. The primary side of system 50 has a common return 25.System 50 also includes a power switch, such as for example a powertransistor 20, that is connected to primary winding Np to form a primarycurrent 23 (Ip) that flows through primary winding Np. Transistor 20 isconfigured to be coupled to a second terminal of primary winding N_(P)to switch transformer 10 for transferring energy from primary windingN_(P) to secondary winding N_(S) and to auxiliary winding N_(A). Acurrent sense element 19 may be connected to transistor 20 to form acurrent sense CS signal that is representative of primary current 23(Ip). In an embodiment, current-sense element 19 may be coupled inseries between transistor 20 and common return 25 for generating thecurrent-sense (CS) signal in response to primary current 23 (I_(P)). Inan embodiment, current sense element 19 may be a resistor, but may beother well-known current sense elements in other embodiments, such asfor example a Sense-FET circuit.

A rectifier 14 (illustrated in general by a diode) and a capacitor 15are connected to secondary winding Ns to facilitate forming an outputvoltage V_(O) and an output current 26 (I_(O)). A load 27 maybeconnected to the outputs of system 50 to receive output voltage V_(O)and output current 26. A feedback circuit 16 may be connected to receiveoutput voltage V_(O) and form a feedback (FB) signal that isrepresentative of the value of output voltage V_(O). An embodiment mayinclude that FB circuit 16 may be configured as a resistor divider thatincludes resistors 17 and 18 coupled between an output terminal and anoutput return 28 of secondary winding Ns. For example, the voltagedivider may include that resistor 17 is coupled to resistor 18 inseries, and the series combination may be coupled between the outputvoltage V_(O) and output return 28. However, feedback circuit 16 mayhave various other embodiments including an optical coupler or other FBcircuits that are well-known to those skilled in the art. Althoughoutput return 28 is illustrated as the same as common return 25, in someembodiments output return 28 may be a different return voltage thancommon return 25.

System 50 includes a control circuit 30 that is configured to reduceringing and spikes in primary current 23 (I_(P)). Control circuit 30 isconfigured to generate a switching signal S_(W) at an output terminalPWM to switch transformer 10 via the power switch, such as for exampletransistor 20. An embodiment of control circuit 30 controls switchingsignal S_(W) in accordance with the FB signal and/or the CS signal forregulating the output (output voltage V_(O) and/or output current 26),for example regulating output voltage V_(O) to a target value. In anembodiment, output voltage V_(O) may be regulated to the target value ortarget range that is within a range of values around a desired value.For example, the desired value may be five volts (5 v) and the targetvalue or target range may be plus or minus five percent (5%) around thefive volts.

An embodiment of control circuit 30 may include a supply terminal VCC,output terminal PWM, a current sense terminal CS, a feedback terminalFB, a compensation terminal COMP, and a common return terminal RT.Terminal RT is configured to be connected to a common return voltagesuch as for example a common ground or other common voltage. In anembodiment, return terminal RT may be connected to return 25.Compensation elements are connected to compensation terminal COMP toprovide frequency compensation for amplifiers within circuit 30. In anembodiment, the compensation elements may include a compensationresistor 22 and a compensation capacitor 24. Resistor 22 and capacitor24 may be coupled together in series and also may be connected in seriesbetween compensation terminal COMP and common return 25.

A resistor 11 may be coupled between input voltage V_(IN) and acapacitor 12 to receive the input voltage V_(IN) and form a supplyvoltage Vcc for circuit 30. An embodiment may include that resistor 11and capacitor 12 may be coupled to the supply terminal VCC of circuit 30to provide the supply voltage to circuit 30. Input voltage V_(IN)charges capacitor 12 through resistor 11 for forming supply voltageV_(CC). Auxiliary winding N_(A) may be coupled to a diode 13 to alsoassist in forming supply voltage Vcc. The auxiliary winding N_(A) may becoupled to capacitor 12 and to the supply terminal VCC of the controlcircuit 30 through diode 13. In response to switching primary windingN_(P), auxiliary winding N_(A) charges capacitor 12 through diode 13 forforming the supply voltage V_(CC). Resistor 11 may assist in forming Vccduring start-up before circuit 30 has switched transistor 20 asufficient number of times to cause output voltage V_(O) to reach thetarget value. In response to output voltage V_(O) reaching substantiallythe target value, supply voltage Vcc may reach the desired operatingvoltage for circuit 30. Although transistor 20 is illustrated asexternal to circuit 30, in some embodiments transistor 20 may be a partof circuit 30. The feedback (FB) signal is coupled to the feedbackterminal FB of control circuit 30 to achieve feedback regulation.Current-sense element 19 is further coupled to supply the CS signal tothe CS terminal of control circuit 30. Thus, control circuit 30 receivesthe current-sense (CS) signal for generating the switching signal S_(W)or alternately for regulating primary current 23.

An embodiment of circuit 30 may include a leading edge blanking (LEB)circuit 39. Circuit 39 may be configured to receive the CS signal fromthe CS input and ignore or blank portions at the leading edge of changesin the CS signal. Thus, circuit 39 may not pass the initial portion ofchanges in the received CS signal to the output of circuit 39. Circuit39 is configured to form another current sense (CS) signal that is alsorepresentative of primary current 23 but the leading edge is blanked toeliminate noise spikes in the CS signal. Therefore, the signal fromcircuit 39 is also referred to as the current sense (CS) signal that isrepresentative of current 23. Such LEB circuits are well known to thoseskilled in the art.

As will be seen further hereinafter, circuit 31 may be configured tohave several different operating modes or sequences that include anormal operating mode, a start-up operating sequence or start-upsequence, and a non-switching mode. The normal operating mode is a modein which circuit 30 is switching transistor 20 with switching signalS_(W), and regulating output voltage V_(O) to the target value, thus,output voltage V_(O) is maintained to the target value, thus, within therange of the target value. Those skilled in the art will appreciate thatthe normal operating mode may also include a burst mode operation orskip-cycle operation wherein switching signal S_(W) may not be switchedfor a number of cycles of the switching frequency in order to maintainoutput voltage V_(O) within the target value. The skip-cycle operationis part of the normal operating mode because it maintains output voltageV_(O) within the range of the target value.

The non-switching mode is a mode in which circuit 30 is not switchingthe switching signal S_(W) and output voltage V_(O) is not within therange of the target value. The non-switching mode may be a result avariety of conditions such as power not being applied to circuit 30, ora fault condition that may occur even though operating power is appliedto circuit 30. For example, when power is first applied to system 50(FIG. 1), thus to circuit 30, circuit 30 has not been switching signalS_(W) due to the lack of operating power which results in anon-switching mode. In another example, the operating power for circuit30 may be removed while circuit 30 is operating. Thus, circuit 30 may beconfigured to detect that the operating power has decreased to less thana lower threshold value and to stop switching of the SW signal whichresults in a non-switching mode. The non-switching mode may last untilthe operating power returns to greater than the threshold value. In anembodiment, a portion of circuit 30 (not shown) may detect a faultcondition. The fault condition may result from various conditions, suchas for example an overvoltage condition of output voltage V_(O), forexample output voltage V_(O) having a value much greater than the highrange of the target value, such as approaching a value that may damagesome circuitry. Circuit 30 may be configured to detect such a faultcondition and thus may terminate switching of switching signal S_(W)resulting in a non-switching mode. The fault condition may also resultfrom an over current condition of output current I_(O), or otherwell-known fault condition. Portions of circuit 30 may be configured tostop the switching of signal S_(W) in response to the fault condition,thus, causing a non-switching mode. In an embodiment, the non-switchingmode may last for a short or a long time interval. For example a shorttime interval of five to ten (5-10) milliseconds, or a long timeinterval of more than ten and up to a hundred or more (10-100 orgreater) milliseconds. An optional embodiment of circuit 30 may beconfigured to detect that signal SW has not been switched for a timeinterval, such as for example the short or long time interval, and tocause circuit 30 to operating in the non-switching mode.

As used herein, start-up sequence is intended to mean any operation thatinitiates switching of signal S_(W) after signal S_(W) was not switched.For example, initiate switching of signal S_(W) after signal S_(W) wasnot switched during the non-switching mode. In another example, afterpower is applied (or re-applied) or the fault condition is terminated,circuit 30 may be configured to initiate switching of signal S_(W)according to the start-up sequence, for example after operating in thenon-switching mode. Circuit 30 may be configured to terminate thenon-switching mode and initiate switching of switching signal S_(W)according to the start-up sequence, thus, initiate a start-up sequence.

FIG. 2A schematically illustrates an example of a portion of anembodiment of circuit 30. Control circuit 30 includes a soft-startsignal generation circuit or soft-start circuit 31, a variable frequencyoscillator (OSC) 33, an error amplifier 35, a comparator 37, and aD-type flip-flop 41. Circuit 30 may also include an optional detectcircuit 34 that may be configured to receive a protection signal from acircuit (not shown) that detects a fault condition, such as for exampleone of the previously explained fault conditions. Circuit 34 may alsodetect power being applied to circuit 30 such as after power wasremoved. Optionally, circuit 34 may also be configured to detect a stateof circuit 30 not switching signal S_(W) for a time interval. Circuit 34may have an embodiment that may form a control signal that may be usedto stop the switching of the S_(W) signal, thus cause a non-switchingmode. In an embodiment, circuit 34 may form a signal 36 that is assertedin response to detecting one or more of the fault conditions. Circuit 31may receive signal 36 from circuit 34. In an embodiment, signal 36 maybe an optional enable (EN) that may be used by circuit 31.

Soft-start circuit 31 is configured to form a soft-start frequencycontrol (FC) signal 32 that is received on an oscillator control (OC)input of oscillator 33. Oscillator 33 may be configured to form anoscillation signal V_(OSC) in response to FC signal 32. Oscillationsignal V_(OSC) is coupled to a clock terminal CLK of flip-flop 41 forgenerating the switching signal S_(W). Those skilled in the art willappreciate that in some embodiments, there may be other circuitrybetween the output of flip-flop 41 and the S_(W) signal that is providedto the PWM terminal. For example, there may be a driver buffer or somelogic circuit to form certain edges or, for some application a dead timebetween certain edges of the S_(W) signal. An embodiment may include anoptional AND gate, illustrated in dashed lines, between the Q output offlip-flop 41 and the S_(W) signal. In such an embodiment, circuit 34 mayor may not receive the S_(W) signal. The optional AND gate may receivethe EN signal and block the switching of flip-flop 41 from affecting theS_(W) signal. An input terminal D of flip-flop 41 is coupled to a supplyvoltage V_(d) in order to generate switching signal S_(W) at an outputterminal Q of flip-flop 41. The frequency of oscillation signal V_(OSC)is controlled by the level of the signal received on the OC inputterminal of oscillator 33, for example FC signal 32. Thus, the frequencyof the switching signal S_(W) is determined by the frequency of theoscillation signal V_(OSC). For example, during the start-up sequence,FC signal 32 can control the switching frequency of switching signalS_(W).

FIG. 2B is a graph having a plot 45 that illustrates an example of anembodiment of FC signal 32. The abscissa indicates time and the ordinateindicates increasing value of the illustrated signal. This descriptionhas references to FIG. 2A and FIG. 2B.

During the start-up sequence, control circuit 30 is configured togradually increase the switching frequency of the switching signalS_(W). In an embodiment, circuit 30 may be configured to increase thefrequency of switching signal S_(W) from approximately zero hertz to afrequency at which output voltage V_(O) achieves the target value, suchas is within the range of the target value. For example, if theswitching of the switching signal S_(W) is terminated, the frequency issubstantially zero. An embodiment of circuit 30 may be configured toinitiate a start-up sequence and start switching signal S_(W) at someminimum frequency, such as for example a frequency no less thanapproximately twenty (20) KHz, thus the frequency would step fromsubstantially zero to approximately the minimum frequency, then increasein response to the value of the signal received on the OC input ofcircuit 33. Alternately, circuit 30 may be configured to slowly increasethe frequency of switching signal S_(W) from approximately the minimumfrequency to a frequency that is greater than the minimum frequencyindependently of output voltage V_(O). An embodiment of circuit 30 maybe configured to slowly increase the frequency of switching signal S_(W)in a number of discrete increments. It has been found that graduallyincreasing the switching frequency during the start-up sequence reducesthe amount of ringing and spikes formed in primary current 23 (I_(P))during the start-up sequence. In an embodiment, the frequency may beincreased during the start-up sequence. In an example embodiment, theswitching frequency may be increased from the minimum frequency to thetarget frequency over an interval of approximately ten micro-seconds (10μsec.) to an interval of approximately eight hundred micro-second (800μsec.). In other embodiments, the frequency may be increased at otherrates.

In an embodiment, an asserted state of the Vosc signal clocks flip-flop41 to assert signal S_(W). Thus, to initiate the on-time of transistor20. The off-time of transistor 20 is initiated by an off-time controlcircuit of circuit 30. The period or cycle of signal S_(W) is the sameas the period of the V_(OSC) signal and is the sum of the on-time andthe off-time, plus some optional dead-time between the switching of thesignals. The off-time control circuit may include error amplifier 35 andcomparator 37. Circuit 30 may be configured to receive the FB signalfrom the FB terminal. The FB signal may be coupled to a negative inputterminal of error amplifier 35. A reference signal V_(ref) may becoupled to a positive input terminal of error amplifier 35. Erroramplifier 35 may be configured to form an error signal in response tothe FB signal and the reference signal. The output of error amplifier 35may also be connected to the COMP terminal to provide frequencycompensation for amplifier 35. The components connected to the COMPterminal form the error signal into a control signal V_(COMP). Controlsignal V_(COMP) is connected to the negative input of comparator 37, andthe current-sense signal CS from LEB circuit 39 is coupled to thepositive input of comparator 37. Comparator 37 generates a reset signalby comparing the control signal V_(COMP) and current-sense signal CS.The reset signal is coupled to the reset input RST of flip-flop 41 forinitiating the off-time of signal S_(W). Thus, the reset signal disablesthe switching signal S_(W) to start the off-time of transistor 20.

Referring to FIG. 2B, assume that prior to a time T0, circuit 30 hasterminated switching of signal S_(W) during a non-switching mode, thusterminated switching transistor 20. Thus, the level of FC signal 32 islow, such as for example at a minimum value. In an embodiment, theminimum value may be approximately zero to stop the operating of circuit33. In other embodiments, the minimum value of FC signal 32 may not bezero but may be at some minimum value that is greater than zero. In suchan embodiment, circuit 33 may still be forming the V_(OSC) signal butthe V_(OSC) signal from circuit 33 may be blocked from affectingswitching signal S_(W). At time T0, circuit 30 initiates the start-upsequence and begins to initiate switching of signal S_(W) at a frequencythat is controlled by the value of FC signal 32. During the start-upsequence, soft-start circuit 31 is configured to gradually increase thevalue of FC signal 32 which gradually increases the frequency of signalV_(OSC), thus, the frequency of signal S_(W). Therefore, circuit 30 isconfigured to increase the frequency of switching signal S_(W) from afirst value to a second value that is greater than the first valueduring the start-up sequence. Gradually increasing the frequency ofswitching signal S_(W) reduces ringing and also reduces spikes in outputcurrent I_(O).

In an embodiment, circuit 30 may be configured to increase the frequencyof signal S_(W) in a number of discrete (or digital) steps asillustrated by plot 45, or alternately may increase the frequencylinearly as illustrated by dashed plot 46. For example, circuit 30 maybe configured to increase signal FC in eight steps or alternatelyincrease it in any number of steps such as for example twelve orsixteen. In an embodiment, soft-start circuit 31 and oscillator 33 maybe configured to operate as a stepwise soft-start control circuit.

FIG. 3A schematically illustrates an example of a portion of anembodiment of a soft-start circuit 105 that may have an embodiment thatmay be an alternate embodiment of circuit 31. Soft-start circuit 105 isconfigured to form FC signal 32 to have a value that increases in eightdiscrete or digital increments. Circuit 105 includes a multiplexer 111,a counter 113, a NAND gate 117, and an AND gate 115. Circuit 105 mayalso have an embodiment that optionally may include a timing circuitthat may be configured to form a clock (CK) signal that may be used toclock counter 113. An example embodiment of the timing circuit may be anoscillator 107. In an embodiment, oscillator 107 may operate a lowerfrequency than any of the frequencies of signal S_(W). The CK signal mayhave a frequency that is ten (10) or more times less than any of thefrequencies of signal S_(W). For example, an embodiment of oscillator107 may be a counter that is clocked by the V_(OSC) signal. In anotherembodiment oscillator 107 may be a separate oscillator from oscillator33. For example, oscillator 107 may operate at a fixed frequency. Anembodiment of soft-start circuit 105 may include a voltage divider 110that is configured to form a plurality of reference voltagesV_(ref0)˜V_(ref7). Each individual reference voltage may be coupled to arespective input terminal of a multiplexer 111 for forming the discretevalues of FC signal 32. Multiplexer 111 has three selection inputterminals SEL0, SEL1, and SEL2 that select one of the input terminals tothe output. The selection input terminals SEL0, SEL1, and SEL2 arecoupled to a respective output terminal (Q0, Q1 and Q2) of counter 113for selecting one of the reference voltages V_(ref0)˜V_(ref7) as the FCsignal 32.

FIG. 3B is a graph having plots that illustrate some of the signalsformed during an example of an operation of circuit 105. The abscissaindicates time and the ordinate indicates increasing values of theillustrated signal. A plot 120 illustrates the enable (EN) signal, aplot 121 illustrates the clock (CK) signal, and a plot 127 illustratesFC signal 32. This description has references to FIG. 2A, FIG. 3A, andFIG. 3B.

Assume that prior to a time TO, circuit 30 is not switching signal S_(W)and that the EN signal is negated. For example, the EN signal may be thesignal formed by circuit 34 (FIG. 2A). The negated EN signal resetscounter 113 to a zero value which causes multiplexer 111 to selectreference signal V_(REF0) to be the level of FC signal 32. The negatedEN signal maintains counter 113 reset and blocks the CK signal fromaffecting counter 113.

Assume that at a time T1, circuit 30 initiates switching of signal S_(W)and initiates a start-up sequence. Circuit 30 then asserts the EN signaland counter 113 starts to count up from zero to seven in response toeach pulse of the CK signal. The EN signal may be formed by circuit 34or may be formed by another portion of circuit 30 (not shown).Multiplexer 111 may be formed to sequentially select the referencevoltages V_(ref1)˜V_(ref7) as the value of FC signal 32 according to thecounter value of counter 113. Accordingly, the level of FC signal 32will be gradually increased during the start-up sequence. In response tothe increasing value of FC signal 32, oscillator 33 (FIG. 2A) willcorrespondingly increase the frequency of the oscillation signalV_(OSC). Circuit 30 will gradually increase the switching frequency ofswitching signal S_(W) during the start-up sequence. Once counter 113counts up to seven, the levels of the output signals outputted by theoutput terminals Q0, Q1, and Q2 of counter 113 are all asserted whichnegates the output signal of NAND gate 117 and consequently AND gate 115which blocks the CK signal from counting counter 113, thus, counter 113will stop counting. FC signal 32 remains at the maximum value during theremainder of the operation of circuit 30, until circuit 30 again stopsswitching signal S_(W) during the non-switching mode. In an embodiment,circuit 30 may be configured to assert signal EN in response to stoppingswitching signal S_(W) for the non-switching mode. For example, circuit30 may be configured to assert the EN signal to initiate thenon-switching mode. Thus, circuit 30 is configured to gradually increasethe frequency of signal S_(W) as the duration of the start-up sequenceincreases.

The output terminals Q0, Q1, and Q2 of the counter 113 are furtherrespectively coupled to the first input terminal, the second inputterminal, and the third input terminal of NAND gate 117. The outputterminal of NAND gate 117 is coupled to the third input terminal of ANDgate 115. The first input terminal and the second input terminal of ANDgate 115 receive respectively the EN signal and the CK signal. Theoutput terminal of AND gate 115 is coupled to the CLK of counter 113.Counter 113 counts up according to the CK signal and generates therespective output signals outputted by the output terminals Q0, Q1, andQ2 according to the value of counter 113. The EN signal is also coupledto the reset terminal RST of counter 113 for resetting its countervalue. The reset terminal RST is configured to cause a reset of counter113 in response to a negated value. Circuit 105 may be configured toform FC signal 32 change each step at a time interval that is a cycle ofa frequency that can be anywhere in a range of approximately twenty KHzto approximately one hundred KHz.

Those skilled in the art will appreciate that although circuit 105 isillustrated to form FC signal 32 in a series of eight (8) steps, circuit105 may have less or more than eight (8) steps. Additionally, circuit105 may be implements as a circuit that forms FC signal 32 to increasein an analog manner. For example, may form FC signal 32 as a ramp signalor waveshape that changes in an analog manner.

FIG. 4A schematically illustrates an example of a portion of anoscillator circuit or oscillator 60 that may have an embodiment that maybe an alternate embodiment of oscillator 33 (FIG. 2A). Oscillator 60 mayinclude two variable current source (CCCS) circuits or current sources61 and 62, a resistor 64, two switches 66 and 67, a capacitor 69, twocomparators 71 and 72, and an SR flip-flop 74. Oscillator 60 may have aninput configured to receive an oscillator control (OC) signal 63 andform oscillator signal V_(OSC). In an embodiment, such as for examplethe embodiment of FIG. 2A, oscillator 60 may be configured to receive FCsignal 32 as oscillator control (OC) signal 63. OC signal 63 is coupledto a control input of current source 61. A resistor 64 is coupledbetween the control inputs of current sources 61 and 62 for generating acontrol current 65 to the control inputs of each of current sources 61and 62 in response to OC signal 63. Current source 61 is further coupledto the supply voltage V_(DD) to form a charge current I_(C) whose valueis controlled by control current 65. That is, the value of the chargecurrent I_(C) is controlled by OC signal 63. Current source 62 isfurther coupled to the common return RT to provide a discharge currentI_(D) whose value is also controlled by control current 65.

Switch 66 is coupled between current source 61 and a ramp capacitor 69.Switch 67 is coupled between ramp capacitor 69 and current source 62.Ramp capacitor 69 is charged by the charge current I_(C) when switch 66is switched on by output signal V_(OSC), and capacitor 69 is dischargedby the discharge current I_(D) when switch 67 is switched on by aninverse signal outputted by the inverse output terminal Qbar of SRflip-flop 74. Therefore, a ramp signal V_(RAMP) is generated across rampcapacitor 69.

Ramp signal V_(RAMP) is further coupled to the negative input terminalof comparator 71. The positive input terminal of comparator 71 iscoupled to receive a reference voltage V_(OSC) _(_) _(L) that isrepresentative of a lower trip point voltage of V_(RAMP). Comparator 71generates an output signal coupled to a set terminal S of the SRflip-flop 74. Ramp signal V_(RAMP) is also coupled to a positive inputterminal of comparator 72. A negative input terminal of comparator 72 iscoupled to receive a reference voltage V_(OSC) _(_) _(H) that isrepresentative of an upper trip point voltage V_(RAMP.) Comparator 72generates an output signal coupled to a reset terminal R of SR flip-flop74. SR flip-flop 74 generates the output signal V_(OSC) through theoutput terminal Q, and also generates the inverse output signal throughthe inverse output terminal Q bar. FIG. 4B is a graph having plots thatillustrate some of the signals formed during an example of an embodimentof operation of oscillator 60. A plot 76 illustrates an example of OCsignal 63, a plot 77 illustrates an example of an embodiment of thesignal V_(RAMP), and a plot 78 illustrates an example of an embodimentof the V_(OSC) signal. During the start-up sequence, the rising slope ofthe ramp signal V_(RAMP) is gradually increased because the level of thecharge current I_(C) is gradually increased according to the increase ofthe level of OC signal 63. Therefore, the frequency of the output signalV_(OSC) is gradually increased during the start-up sequence.

FIG. 5A schematically illustrates an example of a portion of anembodiment of a control circuit 130 that may have an embodiment that maybe an alternate embodiment of circuit 30 (FIG. 2A). Circuit 130 issubstantially the same as circuit 30 except that circuit 130 alsoincludes a selection circuit 132. An embodiment of circuit 130 may beconfigured to terminate the start-up sequence in response to a change inload 27 (FIG. 1). Alternately, circuit 130 may be configured toterminate the start-up sequence and reduce the frequency of switchingsignal S_(W) in response to a reduction in power required by load 27.Alternately, circuit 130 may be configured to terminate the start-upsequence and reduce the frequency of switching signal S_(W) in responseto output voltage V_(O) reaching the target value.

Selection circuit 132 is configured to receive FC signal 32 formed bycircuit 31 and to also receive control signal V_(COMP). An embodiment ofselection circuit 132 may be configured to form OC signal 63 as eitherFC signal 32 or control signal V_(COMP). For example, an embodiment ofcircuit 132 may be configured to select FC signal 32 or V_(COMP) as theinput signal OC signal 63 to oscillator 33 according to the smallestlevel between FC signal 32 and control signal V_(COMP). In anembodiment, selection circuit 132 may be formed to select either controlsignal V_(COMP) or FC signal 32 as the input signal OC 63 that isreceived by oscillator 33 for controlling the switching frequency of theswitching signal S_(W).

FIG. 5B is a graph having plots that illustrate examples of some of thesignals that may be formed during an example of an operation of anembodiment of circuit 130. A plot 133 illustrates an example of valuesof control signal V_(COMP), a plot 134 illustrates an example of valuesof FC signal 32, and a plot 135 illustrates examples of OC signal 63.This description has references to FIG. 1, FIG. 5A, and FIG. 5B.

Assume that at a time prior to a time T0, circuit 130 is not switchingsignal S_(W) as a result of a non-switching mode. Also assume that theoutput voltage V_(O) is not regulated and is a low value because circuit130 is not switching signal S_(W). Since the output voltage is low, theoutput of amplifier 35 (FIG. 2A) would be saturated and VCOMP would be ahigh level. Thus, the level of the control signal V_(COMP) is higherthan the level of FC signal 32. In other non-switching mode conditions,such as for example the output voltage V_(O) having a value greater thanthe target value, a portion of circuit 30 could be formed to detect thenon-switching of signal S_(W) and the high V_(O) value, and causeV_(COMP) to have a high value. For example, circuit 34 (FIG. 2A) coulddetect the conditions.

Assume that at time T0 circuit 130 initiates switching of signal S_(W),and also initiates a start-up sequence. Since the level of controlsignal V_(COMP) is higher than the level of FC signal 32, selectioncircuit 132 selects FC signal 32 as OC signal 63 to oscillator 33. Thus,the switching frequency of switching signal S_(W) is controlled by thevalue of FC signal 32. Oscillator 33 changes the frequency of switchingsignal S_(W) as the value of FC signal 32, thus OC signal 63, changes.Assume that at a time T1, the output voltage V_(O) reaches substantiallythe target value and V_(COMP) responsively changes. Assume for thisexample that the value of V_(COMP) becomes lower than the level of FCsignal 32, therefore selection circuit 132 selects V_(COMP) as OC signal63. Thus, circuit 130 terminates the start-up sequence in response tocircuit 130 regulating output voltage V_(O) to the target value. Thus,in this example embodiment the switching frequency of switching signalS_(W) is controlled by the control signal V_(COMP) during normaloperation or alternately while the output voltage V_(O) is regulated oralternately while the output voltage V_(O) is the target value. Thus,circuit 130 is configured to gradually increase the frequency of signalS_(W) as the duration of the start-up sequence increases.

FIG. 6A schematically illustrates an example of a portion of anembodiment of a selection circuit 136 that may have an embodiment thatmay be an alternate embodiment of circuit 132 (FIG. 5A). Selectioncircuit 136 may have an embodiment that operates substantially identicalto the operation of circuit 132. Circuit 136 includes a diode 137, abuffer 138, and a resistor 139. Circuit 136 receives FC signal 32,V_(COMP), and responsively forms OC signal 63. A cathode of diode 137receives FC signal 32, and an anode of diode 137 is coupled to an outputterminal of circuit 136. An input terminal of buffer 138 receivesV_(COMP). Resistor 139 is coupled between an output terminal of buffer138 and the anode of diode 137. Circuit 136 is configured to couple FCsignal 32 to the output as OC signal 63 in response to FC signal 32having a value (or level) that is less than the value (or level) ofV_(COMP). In response to a V_(COMP) value (or level) that is less than avalue (or level) of FC signal 32, circuit 136 is configured to coupleV_(COMP) to the output as OC signal 63.

FIG. 6B schematically illustrates an example of a portion of anembodiment of a selection circuit 150 that may have an embodiment thatmay be an alternate embodiment of either of circuits 132 or 136.Selection circuit 150 may have an embodiment that operates substantiallyidentical to the operation of circuit 132. An embodiment of circuit 150may include a comparator 152, an inverter 154, a first switch 155 (SW1),and a second switch 156 (SW2). Circuit 150 is configured to receive FCsignal 32 at a first input, to receive V_(COMP) at a second input, andto form OC signal 63 at an output of circuit 150. In an embodiment, FCsignal 32 is coupled to a first terminal of first switch 155 (SW1), andthe second terminal of first switch 155 (SW1) is coupled to the outputterminal of circuit 150. FC signal 32 is also coupled to the positiveinput terminal of comparator 152. V_(COMP) is commonly coupled to thenegative input terminal of comparator 152 and to a first terminal ofsecond switch 156 (SW2). A second terminal of second switch 156 (SW2) iscoupled to the output terminal of circuit 150. Comparator 152 comparesFC signal 32 and V_(COMP) to generate a control signal at the outputterminal of comparator 152 for controlling first switch 155 (SW1)through the inverter 154. The control signal of comparator 152 is alsoused to control the second switch 156 (SW2).

Circuit 150 is configured to couple FC signal 32 to the output as OCsignal 63 in response to FC signal 32 being less than V_(COMP). Forexample, if the level of FC signal 32 is lower than the level ofV_(COMP), first switch 155 (SW1) is switched on and second switch 156(SW2) is switched off, and therefore FC signal 32 is output as OC signal63 through first switch 155 (SW1). Circuit 150 is also configured tocouple V_(COMP) to the output as OC signal 63 in response to V_(COMP)being less than FC signal 32. For example, V_(COMP) is output as OCsignal 63 through second switch 156 (SW2) when the level of V_(COMP) islower than the level of FC signal 32 and the second switch 156 (SW2) isswitched on. Thus, circuit 150 is configured to gradually increase thefrequency of signal S_(W) as the duration of the start-up sequenceincreases.

FIG. 7A schematically illustrates an example of a portion of anembodiment of a control circuit 170 that may have an embodiment that maybe an alternate embodiment of circuit 30 or circuit 130. An embodimentof circuit 170 may be substantially the same as circuit 130 and mayoperate substantially the same as circuit 130 except that circuit 170also includes a current limit circuit. An embodiment of circuit 170 maybe configured to limit a peak value of primary current 23 during thestart-up sequence. Circuit 170 may also be configured to control orlimit the peak value of current 23. An embodiment may include thatcircuit 170 is configured to increase the peak value of current I_(P)from a first value to a higher second value during the start-upsequence. In an embodiment, circuit 170 may be configured to increasethe peak value of current I_(P) at a rate that is similar to an increasein the frequency of the V_(OSC) signal. Circuit 170 may have anembodiment that may be configured to increase the peak value of currentI_(P) according to the value of FC signal 32 during the start-upsequence. Circuit 170 may also be configured to terminate the start-upsequence in response to a change in load 27 (FIG. 1).

An embodiment of the current limit circuit may be configured to receiveFC signal 32 on a first input, to receive the CS signal on a secondinput and form a control signal 179 on an output of the current limitcircuit. Circuit 170 may be formed to terminate the on-time of thesignal S_(W) in response to an asserted state of signal 179. Anembodiment of the current limit circuit may be configured to include acomparator 176 and an OR gate 178. In an embodiment, FC signal 32 may becoupled to a negative input terminal of comparator 176, and a positiveinput terminal of comparator 176 may be coupled to receive the CSsignal. The output of comparators 176 and 37 may be coupled to the inputterminals of OR gate 178, and the output of OR gate 178, such as forexample signal 179, may be coupled to the reset input RST of flip-flop41. Comparator 176 may be configured to compare FC signal 32 with the CSsignal to control the on-time of the switching signal S_(W) for duringthe start-up sequence. Comparator 37 may be configured to compareV_(COMP) with the CS signal to control the on-time of switching signalS_(W) for controlling current I_(P) (as shown in FIG. 1) during thenormal operation period of circuit 170. For example after terminatingthe start-up sequence.

FIG. 7B is a graph having plots that illustrate examples of some of thesignals that may be formed during an example of an operation of anembodiment of circuit 170. A plot 181 illustrates an example of valuesof control signal V_(COMP), a plot 182 illustrates an example of valuesof FC signal 32, and a plot 183 illustrates examples of current I_(P)flowing through primary winding N_(P) of transformer 10 including thepeak value thereof. This description has references to FIG. 1, FIG. 7A,and FIG. 7B.

Assume that at a time prior to T0, circuit 170 is not switching signalS_(W) during the non-switching mode. Also assume that the output voltageV_(O) is not regulated because circuit 170 is not switching signalS_(W). Thus, the level of the control signal V_(COMP) is higher than thelevel of FC signal 32.

Assume that at time T0, circuit 170 initiates switching of signal S_(W),and also initiates a start-up sequence. Therefore, the output voltageV_(O) isn't regulated to the target value yet during the start-upsequence. The level of control signal V_(COMP) is higher than the levelof FC signal 32, therefore, the output of comparator 176 is asserted inresponse to the CS signal before the output of comparator 37. Theasserted output of comparator 176 results in terminating the on-time ofsignal S_(W). Therefore, the switching signal S_(W) is disabled bycomparator 176. Consequently, the peak value of current I_(P) is limitedaccording to the value of FC signal 32 during the start-up sequence. Theon-time of the switching signal S_(W) is gradually increased, thus thepeak value of current I_(P) is gradually increased, in response to theincrease of the level of FC signal 32 during the start-up sequence.Thus, circuit 170 is configured to gradually increase the peak value ofcurrent Ip as the duration of the start-up sequence increases.

Assume that at a time T1, the output voltage V_(O) reaches substantiallythe target value and V_(COMP) responsively changes. Assume for thisexample that, in response, the value of V_(COMP) becomes lower than thelevel of FC signal 32. In this example, circuit 170 terminates thestart-up sequence in response to circuit 170 regulating output voltageV_(O) to the target value. Consequently, the value of the CS signalreaches the value of V_(COMP) before it can reach the value of FC signal32 thereby asserting the output of comparator 37 instead of comparator176. The asserted state of the output of comparator 37 terminates theon-time of switching signal S_(W). Thus, the peak value of current I_(P)is limited by the control signal V_(COMP) during the normal operationperiod. The on-time of the switching signal S_(W) is also controlled bythe control signal V_(COMP) during the normal operation period oralternately while the output voltage V_(O) is regulated.

FIG. 8 schematically illustrates an example of a portion of anembodiment of a buck power supply system 200. System 200 includescircuit 30 or alternately any of circuits 130 or 170. The exampleembodiment of system 200 includes an inductor 206 but does not includetransformer 10 and auxiliary winding N_(A) of system 50. Additionallydiode 13 and capacitor 12 are also not included. Thus, resistor 11 iscoupled between input voltage V_(IN) and supply terminal VCC of circuit30 for providing the supply voltage V_(CC) to the supply terminal VCC. Apower transistor 204 is coupled between input voltage V_(IN) and thefirst terminal of inductor 206. The second terminal of inductor 206 iscoupled to the output terminal of system 200 for generating outputvoltage V_(O) and output current I_(O) for a load 210.

The current sense input CS of circuit 30 is coupled to a node 209 formedat the connection of power transistor 204 and inductor 206 to receive CSsignal for sensing the current I_(P) flowing through power transistor204. Circuit 30 generates the switching signal S_(W) at the outputterminal PWM to switch transistor 204 in response to the CS signal.Circuit 30 controls the switching signal S_(W) in accordance with the FBsignal for regulating output (output voltage V_(O) and/or output currentI_(O)) of system 200. A cathode of a rectifier 208 is coupled to node209, and an anode of rectifier 208 is coupled to a common return.

FIG. 9 illustrates an enlarged plan view of a portion of an embodimentof a semiconductor device or integrated circuit 220 that is formed on asemiconductor die 221. In an embodiment, any one of 30, 130, or 170 maybe formed on die 221. Die 221 may also include other circuits that arenot shown in FIG. 9 for simplicity of the drawing. The circuit orintegrated circuit 220 may be formed on die 221 by semiconductormanufacturing techniques that are well known to those skilled in theart.

From all the foregoing, one skilled in the art will appreciate that acontrol circuit for a power supply may comprise:

the control circuit, such as for example one or more of circuits 30,130, and/or 170, configured to operate a switching signal, such as forexample signal SW, at a frequency to switch a power switch, such as forexample transistor 20, and to regulate an output voltage, such as forexample output voltage V0, to a target value;

an oscillator, such as for example circuit 30, configured to form anoscillator signal at the frequency, and to cause the switching signal toswitch at the frequency; and

a first circuit, such as for example circuit 31, configured to controlthe frequency of the oscillator signal to increase during a start-upsequence initiated by the control circuit wherein the control circuitterminates increasing the frequency in response to regulating the outputvoltage to the target value.

In an embodiment, the control circuit may be configured to initiate thestart-up sequence after the switching signal is not switched as a resultof operating in a non-switching mode.

An embodiment may include that the control circuit may be configured toinitiate the start-up sequence in response to power being applied to thecontrol circuit. Another embodiment may include that the first circuitmay be configured to incrementally increase the frequency of theoscillator signal in a number of steps during the start-up sequence.

The control circuit may have an embodiment that may include that thefirst circuit may include a counter that increments and increases thefrequency with each increment of the counter.

In an embodiment, outputs of the counter may drive inputs of amultiplexer to select different multiplexer inputs for each increment ofthe counter.

An embodiment may include that control circuit may include an erroramplifier configured to form an error signal in response to a feedbacksignal that is representative of the output voltage, wherein the firstcircuit is configured to form a control signal, such as for example FCsignal 32, to increase the frequency of the oscillator signal, andwherein the control circuit terminates the start-up sequence in responseto the error signal changing to a value that is less than the controlsignal from the first circuit.

Another embodiment may also include a current limit circuit configuredto limit a peak value of a current through the power switch and toincrease the peak value at a rate corresponding to the frequencyincrease.

In an embodiment, the first circuit may be configured to form a controlsignal to increase the frequency of the oscillator signal, the controlcircuit further including a current limit circuit configured to limit apeak value of a current through the power switch according to the valueof the control signal.

Those skilled in the art will also appreciate that a method of forming acontrol circuit for a power supply may comprise:

forming the control circuit to form a switching signal to switch a powerswitch to regulate an output voltage to a target value;

forming a variable frequency oscillator, such as for example oscillator33, to oscillate at a frequency wherein the control circuit switches theswitching signal at a target frequency in response to the output voltagehaving the target value; and

forming a first circuit, such as for example circuital and/or 132, toinitiate increasing the frequency from a first frequency that is lessthan the target frequency to a second frequency, that is greater thanthe first frequency and is also less than the target frequency,responsively to the control circuit operating in a start-up mode whereinthe first circuit is configured to continue increasing the frequencyuntil the output voltage reaches substantially the target value.

The method may also have an embodiment that may include forming thecontrol circuit to include a skip-cycle circuit that inhibits thecontrol circuit from switching the switching signal while the outputvoltage is within a target range of the target value.

An embodiment of the method may include forming the control circuit tooperate in the start-up mode in response to application of power to thecontrol circuit.

Another embodiment may include forming the control circuit to operate inthe start-up mode in response to the control circuit initiatingswitching of the switching signal after stopping switching of theswitching signal in response to the output voltage being either greaterthan or less than the target value.

An embodiment may include forming the control circuit to operate in thestart-up mode in response to initiating switching of the switchingsignal after stopping switching of the switching signal while the outputvoltage is not approximately the target value.

The method may also have an embodiment that may include forming thefirst circuit to form a control signal that controls the frequencyincluding configuring the first circuit to increase the control signalfrom a first value to a second value during the start-up mode to causethe variable frequency oscillator to increase the frequency from thefirst frequency to the second frequency.

Another embodiment may include forming the first circuit, such as forexample circuit 105, to include a timing oscillator, such as for exampleoscillator 107, that operates at a timing frequency that has a frequencythat is between approximately 100 Hz and approximately 10 kHz.

those skilled in the art will also appreciate that a method of forming apower supply control circuit may comprise:

forming a control circuit to form a switching signal to switch a powertransistor at a frequency to regulate an output voltage of the powersupply to a target value wherein the control circuit is configured tooperate in a normal operating mode and a start-up mode and wherein thecontrol circuit is configured to switch the switching signal at a targetfrequency in response to operating in the normal operating mode; and

configuring a first circuit to control the frequency of the switchingsignal to increase from substantially a first frequency to a secondfrequency that is less than the target frequency in response tooperating in the start-up mode.

The method may also have an embodiment that may include forming thecontrol circuit to include a variable frequency oscillator that formsthe frequency of the switching signal responsively to a control signalreceived from the first circuit wherein the first circuit increases thecontrol signal from a first value to a second value to cause the controlcircuit to responsively increase the frequency of the switching signalfrom the first frequency to the second frequency.

An embodiment may also include configuring the control circuit to limita peak value of current through the power transistor during the start-upmode according to the control of the frequency of the switching signal.

Another embodiment may include configuring the first circuit to form acontrol signal that increases from a first value to a second value tocause the control circuit to responsively increase the frequency of theswitching signal, and configuring the control circuit to limit the peakvalue of the current according to the control signal.

In view of all of the above, it is evident that a novel device andmethod is disclosed. Included, among other features, is forming acontrol circuit to gradually increase the frequency of a switchingsignal of a power supply controller in response to starting, orre-starting, switching of the switching signal after not switching theswitching signal. For example, in response to applying power to thepower supply controller. Gradually increasing the switching frequencyreduces ringing and spikes in the primary current.

While the subject matter of the descriptions are described with specificpreferred embodiments and example embodiments, the foregoing drawingsand descriptions thereof depict only typical and non-limiting examplesof embodiments of the subject matter and are not therefore to beconsidered to be limiting of its scope, it is evident that manyalternatives and variations will be apparent to those skilled in theart. As will be appreciated by those skilled in the art, the exampleform of control circuit 30 is used as a vehicle to explain the operationmethod of gradually increasing the frequency of the switching signal.Those skilled in the art will appreciate that other circuits may be usedto form variable frequency oscillator 33, and other circuitconfigurations may be used to form soft-start circuit 31 as long as thecircuits are configured to gradually increase the frequency of switchingsignal S_(W). Additionally, various types of circuits may be used todetect the non-switching condition and for one or more signals thatcause circuit 30 to operate in the non-switching mode.

As the claims hereinafter reflect, inventive aspects may lie in lessthan all features of a single foregoing disclosed embodiment. Thus, thehereinafter expressed claims are hereby expressly incorporated into thisDetailed Description of the Drawings, with each claim standing on itsown as a separate embodiment of an invention. Furthermore, while someembodiments described herein include some but not other featuresincluded in other embodiments, combinations of features of differentembodiments are meant to be within the scope of the invention, and formdifferent embodiments, as would be understood by those skilled in theart.

1. A control circuit for a power supply comprising: the control circuit configured to operate a switching signal at a frequency to switch a power switch and to regulate an output voltage to a target value; an oscillator configured to form an oscillator signal at the frequency, and to cause the switching signal to switch at the frequency; and a first circuit configured to control the frequency of the oscillator signal to increase during a start-up sequence initiated by the control circuit wherein the control circuit terminates increasing the frequency in response to regulating the output voltage to the target value.
 2. The control circuit of claim 1 wherein the control circuit initiates the start-up sequence after the switching signal is not switched as a result of operating in a non-switching mode.
 3. The control circuit of claim 1 wherein the control circuit is configured to initiate the start-up sequence in response to power being applied to the control circuit.
 4. The control circuit of claim 1 wherein the first circuit is configured to incrementally increase the frequency of the oscillator signal in a number of steps during the start-up sequence.
 5. The control circuit of claim 1 wherein the first circuit includes a counter that increments and increases the frequency with each increment of the counter.
 6. The control circuit of claim 5 wherein outputs of the counter drive inputs of a multiplexer to select different multiplexer inputs for each increment of the counter.
 7. The control circuit of claim 1 wherein the control circuit includes an error amplifier configured to form an error signal in response to a feedback signal that is representative of the output voltage, wherein the first circuit is configured to form a control signal to increase the frequency of the oscillator signal, and wherein the control circuit terminates the start-up sequence in response to the error signal changing to a value that is less than the control signal from the first circuit.
 8. The control circuit of claim 1 further including a current limit circuit configured to limit a peak value of a current through the power switch and to increase the peak value at a rate corresponding to the frequency increase.
 9. The control circuit of claim 1 wherein the first circuit is configured to form a control signal to increase the frequency of the oscillator signal, the control circuit further including a current limit circuit configured to limit a peak value of a current through the power switch according to the value of the control signal.
 10. A method of forming a control circuit for a power supply comprising: forming the control circuit to form a switching signal to switch a power switch to regulate an output voltage to a target value; forming a variable frequency oscillator to oscillate at a frequency wherein the control circuit switches the switching signal at a target frequency in response to the output voltage having the target value; and forming a first circuit to initiate increasing the frequency from a first frequency that is less than the target frequency to a second frequency, that is greater than the first frequency and is also less than the target frequency, responsively to the control circuit operating in a start-up mode wherein the first circuit is configured to continue increasing the frequency until the output voltage reaches substantially the target value.
 11. The method of claim 10 further including forming the control circuit to include a skip-cycle circuit that inhibits the control circuit from switching the switching signal while the output voltage is within a target range of the target value.
 12. The method of claim 10 further including forming the control circuit to operate in the start-up mode in response to application of power to the control circuit.
 13. The method of claim 10 further including forming the control circuit to operate in the start-up mode in response to the control circuit initiating switching of the switching signal after stopping switching of the switching signal in response to the output voltage being either greater than or less than the target value.
 14. The method of claim 10 further including forming the control circuit to operate in the start-up mode in response to initiating switching of the switching signal after stopping switching of the switching signal while the output voltage is not approximately the target value.
 15. The method of claim 10 further including forming the first circuit to form a control signal that controls the frequency including configuring the first circuit to increase the control signal from a first value to a second value during the start-up mode to cause the variable frequency oscillator to increase the frequency from the first frequency to the second frequency.
 16. The method of claim 10 further including forming the first circuit to include a timing oscillator that operates at a timing frequency that has a frequency that is between approximately 100 Hz and approximately 10 kHz.
 17. A method of forming a power supply control circuit comprising: forming a control circuit to form a switching signal to switch a power transistor at a frequency to regulate an output voltage of the power supply to a target value wherein the control circuit is configured to operate in a normal operating mode and a start-up mode and wherein the control circuit is configured to switch the switching signal at a target frequency in response to operating in the normal operating mode; and configuring a first circuit to control the frequency of the switching signal to increase from substantially a first frequency to a second frequency that is less than the target frequency in response to operating in the start-up mode.
 18. The method of claim 17 further including forming the control circuit to include a variable frequency oscillator that forms the frequency of the switching signal responsively to a control signal received from the first circuit wherein the first circuit increases the control signal from a first value to a second value to cause the control circuit to responsively increase the frequency of the switching signal from the first frequency to the second frequency.
 19. The method of claim 17 further including configuring the control circuit to limit a peak value of current through the power transistor during the start-up mode according to the control of the frequency of the switching signal.
 20. The method of claim 19 further including configuring the first circuit to form a control signal that increases from a first value to a second value to cause the control circuit to responsively increase the frequency of the switching signal, and configuring the control circuit to limit the peak value of the current according to the control signal. 